Dispensing method and apparatus for dispensing very small quantities of fluid

ABSTRACT

A fluid dispensing system and method includes a pump to aspirate and expel sample fluid, a fluid dispensing tip, and a metering station. The fluid dispensing tip includes a working fluid and an air gap where the air gap separates the working fluid from the sample fluid. The metering station receives a drop of sample fluid that is at least twice as large as the predetermined volume to ultimately be dispensed. The fluid dispensing tip then withdraws the predetermined volume of fluid from the sample fluid. Precise volumes are ascertained by prior knowledge of the geometry of the fluid dispensing tip and by using an imaging device to monitor an interface of either the sample fluid or working fluid with the air gap within the fluid dispensing tip. The system and method are capable of accurately dispensing very small volumes of sample fluid on the order of 10 picoliters. In addition, the system and method do not require large volumes of sample fluid to prime a pump mechanism.

CROSS-REFERENCE TO RELATED APPLICATIONS

[0001] This application is a continuation-in-part (CIP) application ofU.S. Ser. No. 09/950,700. The complete contents of the parentapplication is incorporated herein by reference.

DESCRIPTION BACKGROUND OF THE INVENTION

[0002] 1. Field of the Invention

[0003] The invention pertains to methods and dispensing apparatusesproviding precise, very small quantities of fluids.

[0004] 2. Description of the Prior Art

[0005] It is important in a variety of industries, such as medicaldiagnostics, biotechnology, and scientific instrumentation, toaccurately dispense very small drops of fluids. Furthermore, it isdesirable to be able to program the volume of the drops so that theamount delivered will be precise and accurate while at the same timeminimizing the amount of a sample required for the dispenser. Someexamples of small volume dispensing devices are described in U.S. Pat.Nos. 5,366,896; 5,919,706; 5,927,547; 5,958,342; 5,998,218; 6,083,762;6,090,348; and 6,100,094. Ink jet printer devices represent an exampleof a technology area where systems and methods for dispensing smallvolumes of fluid have been developed. However, the ink jet printerdevices suffer from the drawback that they often require severalmicroliters of fluid to prime the dispenser passage; even if onlysub-nanoliter sized droplets are dispensed. In many technologies, itwould be advantageous to be able to aspirate a volume of about ananoliter or less without needing to pick up larger amounts. Thisproblem is especially acute in forensic sciences and in biotechnologywhere only limited quantities of sample are available.

[0006] One difficulty with dispensing small volumes of fluid is thenecessity of a tip with a small radius. The small radius results inlarge internal pressures that prevent the fluid from flowing easily fromthe tip. To overcome this limitation, other systems expel fluids byforcibly ejecting the droplets at a high velocity. However, thesesystems suffer from accuracy problems. It would be desirable for asystem to be able to aspirate and deliver small volumes without beingsusceptible to clogging, while still maintaining a high level ofaccuracy.

SUMMARY OF THE INVENTION

[0007] It is an object of this invention to overcome the limitations ofthe prior art, and to provide a highly accurate dispensing device andmethod which allows dispensing controllable droplets of sub nanolitersize without requiring relatively large priming volumes.

[0008] This invention contemplates the use of a pipette or probe thatincludes a working fluid, an air gap, and a sample fluid in thedispensing tip. The pipette or probe is used to first retrieve aquantity of the sample fluid at the tip. In the retrieval, the workingfluid and air gap rise within the pipette or probe, and the sample fluidfills the end of the tip. Then, the invention contemplates dispensing asessile drop onto a substrate. Preferably, a small portion of the sampleremains in the end of the tip, and the tip contacts the outer peripheryof the sessile drop. A camera or other imaging device is used to measurethe diameter and height of the fluid. This information is then used tocalculate the volume inside the tip while it is still in contact withthe sessile drop. Then, precise amounts of fluid in selectively variablequantities are drawn back up into the pipette tip from the sessile drop.The tip is then moved to a desired dispensing location, and the desiredsample fluid is expelled from that remaining in the tip.

[0009] Physically, movement of fluid into a very narrow channel pipetteor probe tip is difficult to achieve. The technique utilized in thisinvention promotes the ability to siphon up sample fluid by differentmechanisms. First, creating a sessile drop physically provides a fluidwith a surface of curvature that will promote siphoning. Laplace's rulestates that the pressure across an interface is proportional tointerfacial (surface) tension and inversely proportional to radius ofcurvature. The small radii inside pipette tips, therefore, leads tolarge pressures. Second, the liquid surface does not move smoothly overthe pipette inside surface because the surface is not energeticallyconstant (i.e., even) and because of what is known as contact anglehysteresis (advancing angles are not equivalent to receding angles). Forthese reasons, fluid motion is not steady; rather it is stop and start,and may often be referred to as stick/slip. Combined with the high andvariable pressures from LaPlace's rule, it is extremely difficult todirectly draw or dispense a specific amount from a continuum of liquid.

[0010] The genesis of the invention is that the dispense volume isseparated from the larger supply volume in a preparatory step before theactual dispense phase. The dispense volume is contained in the end of acapillary tube, separated by an airgap from any system liquid in thepumping system. The exact volume of dispense liquid is set by adjustingthe dispense volume while the tip is immersed in a sessile drop of thesame liquid. The sessile drop has much larger radii of curvature thanthe liquid in the tip, and these larger radii lower the interfacialpressure following Laplace's rule.

[0011] When one ponders any dispense operation, there are the followingtwo phases: setting the volume to dispense, and detaching the dispensedvolume from the remainder of the liquid. This is so basic that it isordinarily not enunciated. Ordinarily both functions are performed bythe same means, and often at the same or very similar times. This istrue whether one considers classical syringe pumps or modern ink-jetprinter mechanisms. The current invention takes a different and uniqueapproach in that it separates the two phases. As a simplistic analogy,the first phase can be thought of as a “ruler” to set or measure thevolume and the second phase can be thought of as “scissors” to separatethe volume from its parent or source. This invention separates the rulerfrom the scissors. Furthermore, there are two kinds of scissors used.

[0012] First Phase: The ruler function is performed by video imageanalysis while the tip is immersed in the sessile drop. The airgap thatis set above the liquid in the tip both permits the accurate volumedetermination through the transparent capillary and is preparatory tothe detachment phase. The detachment phase is now subdivided into twoportions. This is important. The first occurs when the tip is pulled upfrom the sessile drop. The tip breaks clean of the sessile drop becausethe tip is very small. The same Laplace pressures that bedevil uselsewhere ensure that the tip comes out clean, without a hanging pendantdrop. The dispense volume is exactly what is inside the tip and what wasmeasured by video analysis. The impetus for the first portion of thedetachment is the motor driving the tip up and down. Most importantly,it is not the pump proper. The pump is not able to perform thisdetachment. So instead, the motorized Z stage separates the “child”volume (the small volume of sample to be dispensed) from the “parent”volume (the volume of the sessile drop).

[0013] Second Phase: The pump plays a role in the second portion, whichoccurs later when the tip is disposed over the target. The pump pushesthe dispense liquid out of the tip, either rapidly or slowly, as theuser desires. There are applications for all kinds of dispensemomentums, or momenta.

[0014] In summary, the Z motor provides the scissors between the liquidin the tip and the liquid in the sessile drop. The pump provides thescissors between the airgap and the dispensed volume over the target.The larger radius of the sessile drop used in this invention lowers thepressures, and the high frequency vibrations contemplated by thisinvention breaks loose the stick/slip motion . In addition, thisinvention contemplates providing vibrations to the pipette or probe tip.This can be achieved by acoustic or mechanical means (e.g., a piezoceramic element may be driven to sequentially compress and de-compressthe working fluid).

[0015] The method and apparatus of this invention are adaptable torobotic placement of very small fluid samples at precise locations. Thismay have application in certain antibody and DNA detection chips, aswell as in a variety of other applications. For example, by havingprecise quantities of fluid containing an antigen or antibody or singlestranded DNA or any other molecular entity placed on a chip or othersubstrate, it would be possible to optically assess weight differentialswhich are the result of selective bonding or hybridizing reactions.

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] The foregoing and other objects, aspects and advantages will bebetter understood from the following detailed description of thepreferred embodiments of the invention with reference to the drawings,in which:

[0017]FIG. 1 is a schematic view of a fluid dispensing system embodyingthe invention;

[0018]FIG. 2 is a schematic view of the tip depositing a drop of samplefluid onto the metering station;

[0019]FIG. 3 is a schematic view of the tip and a camera embodying animaging device;

[0020]FIG. 4 is a schematic view of the tip with a hanging drop ofsample fluid;

[0021]FIG. 5 is a schematic view of an embodiment of the invention wherea perforated tape is used to provide a metering station for the sessiledrop on an automated basis;

[0022]FIG. 6 is a schematic view of showing a piezo pumpingconfiguration in combination with the perforated tape feature of FIG. 5;and

[0023]FIG. 7 is a schematic view of a focusing feature of the inventionused to determine the droplet size which is to be dispensed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

[0024] As illustrated in FIG. 1, the main components of the system 10include a pump 12, a fluid dispensing tip 14, a working fluid 16, and ametering station 18. The pump 12 functions as a mechanical displacementpump for the purpose of aspirating and dispensing fluid through fluiddispensing tip 14. The resolution of the pump 12 can vary according tothe desired size of dispensed droplets. Preferably, the pump 12 isadapted to aspirate volumes on the order of 100 nanoliters or onemicroliter, but can also aspirate volumes as small as on the order of 10picoliters. Suitable pumps may include piezo-electric driven diaphragmpumps, such as the FTA 4000 available from First Ten Angstroms ofPortsmouth, Va. A preferred embodiment of the pump 18 will be discussedin detail below.

[0025] The fluid dispensing tip 14 is used to dispense specified volumesof fluid. Preferably, the tip 14 is adapted to dispense droplets on theorder of 10 picoliters. The inner diameter of the base 19 of the tip 14can range from about 100 μm to 1000 μm, but it is preferably 400 μm.Preferably the tip 14 is conical in shape and is narrower at the end 20with an inner diameter ranging from about 2 μm to 20 μm. One advantageof having a tip 14 with a wider base 19 is the improved ability of thepump 12 to adjust the level of the fluids within the tip 14. The conicalshape minimizes viscosity induced pressures because most of the tube isrelatively large, it also accommodates a large range of volumes withinthe field of view of the camera (imaging device 40) used in the practiceof this invention. The tip 14 is preferably transparent for inspectionpurposes. Inspection may be performed by an imaging device 40 such as avideo recorder or visually by an operator or by automatic computeranalysis. The tip 14 may be made of any material that is not adverselyaffected by the fluid to be dispensed. Preferred materials includeplastic and glass. Some examples of preferred embodiments include adrawn glass capillary or a fused silica fine bore tube, as discussed inmore detail below.

[0026] A working fluid 16 is contained in the base 19 of the fluiddispensing tip 14. The working fluid 16 may be any fluid that willneither damage the pump 12 nor affect the measurement of the fluid to bedispensed. The working fluid 16 may be the same as the fluid that is tobe dispensed. Preferably the working fluid is water. An air gap willalways separate the working fluid from the sample.

[0027] The metering station 18 is an inert surface that is adapted toreceive a drop of the dispensed fluid. The inert surface is defined tobe a material that will neither absorb nor significantly reactphysically or chemically with the fluid to be dispensed. Preferably, themetering station 18 is made of a material that will cause the dispensedfluid to bead on the surface of the metering station 18 (e.g., themetering station 18 may be hydrophobic if the fluid to be dispensed iswater-based). The preferred example of a metering station 18 is apolytetrafluoroethylene surface (PTFE commonly referred to as Teflon®).The size of the metering station 18 may vary as long as the meteringstation 18 is large enough to receive a drop of the fluid to bedispensed. In a preferred embodiment discussed in detail below, themetering station can be positioned below the dispensing tip 14 on anautomated basis.

[0028] The pump 12 controls the level of the working fluid 16 in thefluid dispensing tip 14. The portion of the tip 14 that is not filledwith working fluid 16 is filled with air or an inert gas such asnitrogen. When the system 10 retrieves sample fluid 32 from a supply andaspirates it into the tip, this air becomes an air gap 30 between theworking fluid 16 and the sample fluid 32 as shown in FIG. 2. Thefunction of the air gap 30 is to clearly show the interface 34 betweenthe working fluid 16 and the air gap 30 and/or the interface 36 betweenthe sample fluid 32 and the air gap 30. The air gap may be any volumebut preferably ranges from 100 picoliters to 10 nanoliters. With somesample fluids, it may be desirable to use inert atmospheres such asnitrogen; therefore, within the practice of this invention it should beunderstood that the air gap 30 can include air, nitrogen, or any othergas.

[0029] The amount of sample fluid aspirated is controlled by the pump12. Preferably, the pump 12 aspirates an initial quantity of samplefluid 32 from which the final amount dispensed will be taken. The fluiddispensing tip 14 is placed close to the surface of the metering station18. Preferably, the end 20 of the tip 14 is within a few microns of themetering station 18. A portion of the sample fluid 32 is dispensed as asessile drop 38 onto the metering station 18. Preferably, as the sessiledrop 38 is formed, it comes into contact with both the metering station18 and the fluid dispensing tip 14. The sessile drop 38 may have avolume ranging from 10 picoliters to 10 nanoliters. Preferably thesessile drop 38 has a volume of at least twice the ultimately desireddispense volume. Larger volumes lower pressure because of their largerradii of curvature. Preferably the sessile drop 38 is larger than theinner diameter of the end 20 of the tip 14 so that the internal pressureis lowered. Preferably, the sessile drop 38 has a radius of curvature ofequal to or greater than 100 μm. The pump 12 causes a portion of thesample fluid 32 in the sessile drop 38 to be re-aspirated into the tip14. The volume of the sample fluid 32 in the tip 14 can be adjusteduntil it is the desired amount to be dispensed. Because of the practicalnature of moving liquid surfaces very small distances within thepipette, it is often necessary to repetitively move back and forth anditerate to the desired volume in the tip. Preferably, the system can beused to dispense volumes of sample fluid 32 on the order of 1-100picoliters, e.g., 10-25 picolitors, 25-75 picolitors, 50-100 picoliters,etc. The volume of sample fluid dispensed may be as small as 1 picoliterand as large as 10 nanoliters.

[0030] It should be understood that after the volume of sample fluid 32is dispensed at a location or into a vessel selected by the operator,the pipette tip 14 can be reinserted into the sessile drop 38, andadditional small volumes of fluid can be retrieved and dispensed in thesame manner. In this instance, the pump 18 would need to initiallyaspirate the sample fluid 32 from the drop 38 after the pipette tip 14is reinserted, and then the precise volume would be obtained, usually inan iterative process, as discussed above. It should also be understoodthat the process of this invention, which requires first forming asessile drop of the sample fluid, then obtaining a precise volumetricsample from the sessile drop using imaging technologies, and the radiusof curvature advantages of the sessile drop discussed in detail above,can be automated where by dispensing of the sessile drop, and aspirationand volumetric adjustment with imaging assistance, are both performedusing computer control operations. This will allow a large number ofextremely small sample volumes to be produced and processed in anautomated fashion.

[0031] The volume of the sample fluid is verified by visual inspection.As illustrated in FIG. 3, an imaging device 40 may be used to visuallyobserve the interface 34 between the air gap and the working fluid 16 oralternatively the interface 36 between the air gap 30 and the samplefluid 32. The function of the imaging device 40. and associated computersoftware (not shown), is to assess the quantity of the sample fluid 32being drawn into the tip 14 and ultimately being dispensed from the tip14. Many conventional imaging devices and software analysis tools areavailable, e.g., charge coupled display (CCD) cameras, etc. A preferredembodiment for imaging device 40 is discussed in more detail below.

[0032] Once the correct volume of sample fluid 32 is contained in or atthe tip 14, the tip 14 is withdrawn from the sessile drop 38. The tip 14is then moved to a location where the sample fluid 32 is to be dispensed(as is best shown in FIG. 4). The sample fluid 32 is then expelled atthis location. For very small volumes of fluid, there are evaporationproblems if the fluid is hanging from the tip end. For example,picoliters of water can evaporate in seconds. Thus, for these very smallvolumes (on the order of 10 picoliters) this invention takes advantageof knowing the geometry of the tip inside ahead of time (a priori). Thisallows relating the height of the sample in the tip ultimately to thedispensed volume. By adjusting the liquid at the metering station, acorrect volume is obtained (this may take 10 or more up and downcycles). Then all of the sample left in the tip is dispensed. This canbe achieved by pumping action. Vibratory stimulation can also be used inconjunction with pumping for the same stick/slip reasons discussed abovefor aspiration. This allows a precise volume to be dispensed sincesample fluid does not evaporate while inside the tip.

[0033] For larger volumes, e.g., nanoliter quantities, a hanging dropmethodology can be used where the imaging device 40 (or a second imagingdevice not shown) can be used to analyze the size of the drop formed onthe tip end 20. This can be done by assessing the height and diameter ofthe drop. The hanging drop 44 is then touched on the surface of thedispensing location, at which point the hanging drop 44 detaches fromthe end 20 onto the desired location.

[0034]FIG. 5 shows a preferred embodiment of the invention whichautomatically provides a metering station below the pipette tip. Thetime to access the sessile drop for the “ruler” function is a limitationon the rapidity with which drops can be dispensed (throughput). Ratherthan take the dispense tip to a table using a robot, or moving a solidtable under the tip, a perforated tape or other continuously suppliedsurface on which sessile drop formation can occur may serve as a table.One motivation is to facilitate always having a virginal surface for thenew sessile drop, ensuring no cross contamination if different liquidsare used.

[0035]FIG. 5 shows an embodiment where the dispensing tip 14 and pump 12are translatable on the Z axis using a motor and lead screw combination50 which can move the pipette tip 14 up and down, that is, within andout of contact with the sessile drop 38. Other mechanisms for Z axismovement of the pipette tip 14 may also be used in the practice of thisinvention. In the preferred embodiment, a tape 52, having for exampledimensions of 10 mm width, indefinite length, and a repeating pattern ofapproximately 3 mm diameter perforation holes on, for example, 10 mmcenters down the length of the tape 50 is used to provide meteringstations for the sessile drops. In general, the sessile drop surfaceshould be non-reactive and as low a surface energy as possible so thedrop sits with a high contact angle. A polytetrraflouroethlyene (PTFE)or similar surface is preferred. Thus the tape 50 can be made from PTFE.In addition, it may be desirable to laminate a different polymer film onthe back side of the PTFE or similar material to serve as a carrier forbetter mechanical stability.

[0036] The tape 50 is stretched taut by motors on the takeup and supplyreels 54 and 54′(as is shown by arrows T). The takeup and supply reels54 and 54′ may move the tape 52 in one direction guiding the tape 52from the supply reel 54′ to the take up reel 54, or provision forreverse movement of the tape 50 can also be provided such that a sessiledrop can be returned to a position below the pipette tip 14 at somepoint after its previous use. In this way, a single sessile drop can besubdivided into a large number of microscopically small drops.

[0037] An optical sensor 56 can be used to position the tape 50 belowthe dispensing tip 14. As discussed above, the tape 50 is perforated.This allows for significant automation of small volume sample retrievaland dispensing. First, the tape 50 is advanced to provide a virginalsurface for the sessile drop. Then, a precise, small quantity volume offluid is aspirated from the sample as described in detail above. Then,the dispense tip 14 is raised clear of the sessile drop. Then, the tape50 is advanced again after the small volume of fluid is obtained fromthe sessile drop until the dispense tip 14 is positioned over aperforation (this can be determined using the optical sensor 56 andcontroller (not shown). Finally, the tip 14 is lowered through the holein the tape 50 down to the user's surface for dispensing and isdispensed thereon as described above (see FIG. 4).

[0038] The advantages of this scheme are as follows:

[0039] 1) The tip only needs one axis, “Z”, so its mechanism stayssimple and light. This facilitates rapid motion. Preferably, a separateuser-supplied robot carries the whole apparatus to the desired locationunder the dispense mechanism, or brings desired surfaces under thedispense unit.

[0040] 2) The tape can be rapidly advanced, hole to surface, or surfaceto hole.

[0041] 3) The tape facilitates an indefinite (meaning large) number ofnew surfaces for sessile drops to prevent cross contamination.

[0042] 4) When desired, a single sessile drop can be returned under thetip for further dispense volume ruling, so a single sessile drop can besubdivided into an indefinite number of microscopically small drops.

[0043] 5) When finished, the remaining sessile drop liquid can simply berolled up into the takeup reel side spool 54 for disposal. The liquidamounts are small enough that they do not leak out of the spool.

[0044]FIG. 6 shows an embodiment of the invention where a dual diaphragmpiezoelectric pump 60 is used for the aspiration and precise volumetricadjustments, to the sample fluid volume to be dispensed, as discussed inconjunction with FIG. 1 (which shows a pump generally as 12). Inoperation, it is preferable to use a high capacity piezo pump where bothends of the internal cylinder are piezo driven diaphragms. High capacityis means that the pump can displace enough volume (e.g., 10 microliters)that it can self-prime. The pumping system preferably includes of ahigh-capacity piezo pump with a micro valve on its inlet 62 and outlet64. By opening and closing the valves appropriately, the pump 60 canflow liquid indefinitely in either direction. In this mode it actssimilar to an internal combustion engine, with an “intake” and an“exhaust” cycle. It should be understood that the liquid handlingpumping system used in the practice of this invention may comprise apiezo pump backed by a syringe pump, or it may be comprised of simply ofa high-capacity piezo pump 60 as shown in FIG. 6.

[0045] The reason capacity must be considered is that the valves, eventhough they are “micro”, displace a certain volume as they open orclose. If this valve “internal volume” is similar or greater than thepump's, it is very difficult to pump liquid indefinitely in eitherdirection. Instead it sloshes back and forth between the valve and thepump. When the pump exceeds the valve by several times, pumping isacceptably efficient and it “works” from the user's point of view.Finally, “pump indefinitely in either direction,” should be understoodto mean the pump is capable of moving all of the liquid from one glassto another, in the ordinary sense. For example, it may do this 10microliters per cycle and a cycle takes 100 milliseconds, but it can bedone in many cycles. When the valve capacity is excessive compared tothe pump, the fraction of liquid, compared to the pump's internal volume(e.g., 10 microliters), that actually moves through drops rapidly fromclose to 100% to close to 0%.

[0046] In FIG. 6, the user supplied system fluid or “working fluid” 16is retrieved from vessel 66 using tubing 68. The tubing 68 may bemicrobore polyvinyl chloride tubing, such as 0.042″ internal diametertubing available from Lee as TUVA42220900A. However, it should beunderstood that variations in tubing selection and that other transportmechanisms can be substituted for the tubing. Solenoid microvalves 70are positioned on the inlet 62 arid outlet 64 sides of the piezo pump60. These microvalves 70 may be, for example of the type Lee INKA1224212H or any other suitable type. As noted above, the piezo pump 60is used for aspirating and dispensing operations, and works inconjunction with the microvalves 70 to allow pumping indefinitely ineither direction.

[0047] The dispensing tip 14 may be a disposable tip that is connectedbelow the microvalve 70 on the outlet 64 side of the piezo pump 60. If adisposable tip configuration is desired, a hub or fitting 72, such asLeur fitting, can be used for easy attachment and detachment of thedispensing tip 14. As discussed in conjunction with FIG. 5, the tape 50,which may be perforated polyethylene/PTFE tape, is moved under thedispensing tip 14 in an automated fashion. Thus, the piezo pump 60,movement of the tape 50, and sessile drop formation, sample retrieval,and subsequent dispensing operations through perforations 51 in the tape50 can proceed in an automated fashion.

[0048] Various materials can be used for the dispensing tip 14,including drawn glass capillaries (hollow glass tubing that is pulledout while hot, much like a glass blower in Venice would have done it 500years ago) and also fused silica tubing. The fused silica tubing is verystrong but not really transparent. However, it is translucent and anacceptable image can be obtained by using a strong LED light sourcebehind the silica tube. Therefore, it should be understood that it isnot necessary that the dispense tip 14 be limited to glass. It merelyneeds sufficient light transmission that a shadow of the liquid insidethe tip can be detected while at the sessile drop “ruler” station.

[0049] As noted above, tapered tips give an extremely wide volumeholding range for a modest change in Z level of the top of the liquid.This is because volume is proportional to cross-sectional area and thearea increases proportionally to the radius squared. A tapered tip 14gives much higher incremental volume as the tip diameter grows. Thereason we “see” the liquid inside the dispense tip 14 is that this is arefraction image, i.e., a silhouette. The liquid will have (reliably) adifferent index of refraction than the glass or silica tube wall. In thecase of a round tube being used as the tip 14, the shape is curved andthe curved light interface refracts and pushes the backlight away fromthe detector. The liquid appears dark because there is no light comingfrom that region as it was directed, or bent, away.

[0050] The exact tip 14 location, to accuracies of a few microns, can bedetermined by image analysis while the tip is within the sessile drop“ruler” view (FIG. 2 shows the tip 14 in the sessile drop 38). This ishandy because each new tip 14 will fall at a slightly different locationwhen the user replaces tips. Different users may wish to place thesenano and picoliter drops with micron precision on targets that might beonly 10's of microns across, which is far too small to see with thenaked eye. The image analysis measurement is useful because, in thepreferred embodiment and as discussed in conjunction with FIG. 5, thetip has only one axis of motion, Z, up and down, and so reporting theexact location to the user robot allows fine tuning of the eventualdeposition. The Z axis “holds” the X-Y position as it goes up and down.A two-dimensional image of the tip and sessile drop might give us, saysthe “Z” (up and down) and “X” (left and right) axis positions of thetip, but does not provide the “Y”, or in and out location along theviewing axis. This can preferably be obtained with an “Autofocus ” suchas that shown in FIG. 7.

[0051]FIG. 7 shows a camera 80 positioned above a microscope lens 82that is 90° out of alignment with the drop 84 being imaged. Light fromLED 86 passes through a diffuser 88, the drop 84, and prism 90, and isthen directed up to the camera. A number of conventional pieces ofequipment may be used in the configuration shown in FIG. 7. For example,the LED 86 may be a Lumex SSL-LX50939RC/E, 5 mmφ×15 mm; the diffuser 88may be a typical ground glass devices such as that which is availablefrom Edmund Scientific as L32-333, 15 mm×21 mm; the prism 90 is a 90°turning mirror prism, such as a type Edmund Scientific L32-333, 15 mm×21mm; the microscope lens maybe a Navistar 1-61449 +1-61445; and thecamera 80 may be a USB camera. D1 designates the mechanical length ofthe lens, and may be, for example, type 115 mm. D2 and D3 constitute theworking distance of the lens, and may be, for example, 93 mm and 51 mmor 93 mm and 113 mm. D3 must be enough for the lens body to clear thepump. D4 nay be, for example 29 mm, as is the case in the Navitar“precision eye” lens. D5 is the distance focal plane to light diffuserand should be a distance sufficient to collimate late, such as, forexample 10 mm. D6 is the distance from the LED 86 to the diffuser 88,and may be 5 mm. Of course, the dimensions can be varied within thepractice of this invention. The presence of a drop 84 can be detectedusing an emitter 92-detector 94 pair.

[0052] By having a stepper motor on the microscope focus element, bestfocus position (which will happen to be when the center of the tip is inthe focal plane) can be related to a stepper motor step count. The stepcount will preferably have been previously calibrated with the physicallocation of the focal plane. In this way, “Y” can be extracted. Thisextraction of “Y” information is good enough to be useful in positioningthe tip 14. Of course, other means for locating the position of the tip14 are possible within the practice of this invention.

[0053] In the preferred embodiment shown in FIG. 7, the same camera,i.e., imaging device, that measures liquid volume in the tip also canmeasure the mechanical location of the tip. Z and X are obvious in theimage, but Y is not, if I assume Y is measured along the viewing axis ofthe camera (i.e., perpendicular to the focal plane that contain Z andX). So the same imaging device can measure volumes and also fix the tippositioning with respect to the reference frame of the apparatus. Itsaccuracy (resolution) is better in Z and X, but it is still acceptablein Y as long as you can calibrate the motor position to the physicallens position. Focusing is accomplished by moving the first lens insidethe microscope back and forth, along the Y axis. A motor can drive thismechanism. The actual distance from the first glass surface to the focalplane is the working distance of the microscope. This is known, adatasheet value. If I know the mechanical position of the first glasssurface, from the motor drive, then I know where the focal planelies—which is the Y location of the tip central axis if I have focusedon the tip apex (which is recommended).

[0054] There are several points in the drop image that fall within theplane through the central axis of the tip. We choose those points forour autofocus. The autofocuss can be understood better with reference toa little geometry. Image the tip as a cylindrically symmetric deviceabout a vertical central axis. We locate the tip by the X and Ypositions of this central axis. This central axis is right down the boreof the tube. The bottom of the tip sets the Z location. As the tip movesup and down, its X and Y positions do not change (assuming a wellconstructed device). We say X is sideways in the image and Y is theperpendicular axis we can not directly see in the image—its position iswhat sets focus. If the tip's Y value happens to fall in the focal plane(an X-Z plane the “working distance” from the first glass surface), thenthe image is in focus. The utility of all this is that I can report tothe host, or user, robotic controller the exact X, Y, and Z values ofthe tip apex. That controller can measure from my mounting surface andfigure out (by simple algebra) where to move me or the same so the tipcan be precisely positioned over the desired location on the sample.

[0055] Other imaging and movement mechanisms may also be employed withinthe context of this invention.

[0056] While the invention has been described in terms of its preferredembodiments. Those skilled in the art will recognize that the inventioncan be practiced with modification within the spirit and scope of theappended claims.

I claim:
 1. An apparatus for dispensing specified volumes of fluid, theapparatus comprising: a fluid dispensing tip, said fluid dispensing tipbeing configured to contain 1 picoliter to 10 nanoliters of a samplefluid at an end, an air gap positioned above the sample fluid, and aworking fluid positioned above said air gap; a piezo pump adapted tomaintain said working fluid in said fluid-dispensing tip and adapted toaspirate a first volume of said sample fluid into said fluid dispensingtip and expel said first volume of said sample fluid from said fluiddispensing tip; a metering station having an inert surface positioned toreceive a drop of said sample fluid from said fluid-dispensing tip; andmeans for selectively retrieving a second volume of said sample fluidfrom said drop on said metering station which is smaller than said firstvolume and dispensing said second volume of said sample fluid at adesired location.
 2. An apparatus for dispensing specified volumes offluid, the apparatus comprising: a fluid dispensing tip, said fluiddispensing tip being configured to contain 1 picoliter to 10 nanolitersof a sample fluid at an end, an air gap positioned above the samplefluid, and a working fluid positioned above said air gap; a pump adaptedto maintain said working fluid in said fluid-dispensing tip and adaptedto aspirate a first volume of said sample fluid into said fluiddispensing tip and expel said first volume of said sample fluid fromsaid fluid dispensing tip; a metering station having an inert surfacepositioned to receive a drop of said sample fluid from saidfluid-dispensing tip; means for selectively retrieving a second volumeof said sample fluid from said drop on said metering station which issmaller than said first volume and dispensing said second volume of saidsample fluid at a desired location; and a means for autofocussing on adrop of sample fluid being expelled from said dispensing tip.
 3. Anapparatus for dispensing specified volumes of fluid, the apparatuscomprising: a fluid dispensing tip; a pump for aspirating fluid withinsaid fluid dispensing tip, and for forcing said fluid to be dispensedfrom said fluid dispensing tip; a tape having an inert surfacepositioned to receive sample fluid in the form of a drop of a firstvolume from said fluid-dispensing tip, said tape being translatableunder said fluid-dispensing tip so as to receive multiple drops ofsample fluid at multiple locations; and means for selectively retrievinga second volume of said sample fluid from said drop on said meteringstation which is smaller than said first volume and dispensing saidsecond volume of said sample fluid at a desired location.
 4. Theapparatus of claim 3 wherein said tape has apertures therethough, andwherein said means for selectively retrieving and dispensing said secondvolume causes said fluid dispensing tip 14 to pass through at least oneof said apertures during dispensing of said second volume.
 5. Theapparatus of claim 3 wherein said dispensing tip is translatable in aZ-axis.
 6. The apparatus of claim 3 wherein said fluid dispensing tip isconfigured to contain 1 picoliter to 10 nanoliters of a sample fluid atan end, an air gap positioned above the sample fluid, and a workingfluid positioned above said air gap.
 7. The apparatus of claim 6 whereinsaid pump is adapted to maintain said working fluid in saidfluid-dispensing tip and adapted to aspirate a first volume of saidsample fluid into said fluid dispensing tip and expel said first volumeof said sample fluid from said fluid dispensing tip.
 8. The apparatus ofclaim 7 wherein said pump is a piezo pump.
 9. The apparatus of claim 3wherein said pump is a piezo pump.
 10. The apparatus of claim 3 whereinsaid dispensing tip is transparent or translucent, and said means forselectively retrieving and dispensing said second volume of sample fluidincludes an imaging device which is used to detect an interface in saiddispensing tip of an air gap and a fluid.
 11. The apparatus of claim 10further comprising a means for autofocussing on a drop of sample fluidbeing expelled from said dispensing tip.
 12. The apparatus of claim 3further comprising a means for advancing said tape in at least onedirection.
 13. The apparatus of claim 3 further comprising a means foradvancing said tape in at least two opposite directions.
 14. A methodfor dispensing volumes of fluid, comprising the steps of: aspirating asample fluid into a fluid dispensing tip; dispensing a first volume ofsaid sample fluid onto a surface of a tape which passes under saiddispensing tip to form a drop, said tape having a plurality of surfaceson which drops may be dispensed which are separated by a plurality ofapertures which pass through said tape; aspirating a portion of saiddrop into said fluid dispensing tip, said portion constituting a secondvolume of said sample fluid which is smaller than said first volume; andextending said fluid dispensing tip through at least one perforation insaid tape, and dispensing said portion from said fluid dispensing tip.